Automobile charger

ABSTRACT

A novel automobile charger comprises a direct current (DC) voltage supply, wherein a positive pole of the DC voltage supply is connected with a first end or a first lead of a DC-to-DC module, a first end of a battery voltage detection module and a first end of a load module simultaneously while a negative pole of the DC voltage supply is connected with a second end of the DC-to-DC module, a first end of a microcontroller, a first end of an automobile start control module and a second end of the battery voltage detection module simultaneously. A third end of the DC-to-DC module is connected with a second end of the microcontroller. Third, fourth, and fifth ends of the microcontroller are connected with a third end of the battery voltage detection module, a second end of the automobile start control module and a first end of a load detection module respectively. A second end of the load detection module is connected with a third end of the automobile start control module and a second end of the load module simultaneously.

RELATED APPLICATIONS

This application claims the benefit of priority of Chinese application no. 201420212173. 5 filed Apr. 28, 2014, the entire content of which is incorporated herein by reference.

BACKGROUND

The present disclosure relates to an automobile charging device, in particular relates to a novel automobile charger with a safe power supply charging quickly.

Automobile charging is a big issue of traveling by automobile for those automobile fans and businessmen, the maturity of the technology thereof is one of the critical factors restricting the application of the automobile charger. However, current automobile chargers have common problems of not able to automatically detect whether a load is connected, whether an electrode is connected with an automobile storage battery reversely, whether an automobile engine or the storage battery has a reverse current, whether the battery state is suitable for heavy current power generation and so on. Accordingly, the present disclosure provides a novel automobile charger with the safe power supply charging quickly to solve the problems mentioned above, thus making the automobile charging safe, quick, mature and propagable.

SUMMARY

A purpose of the present disclosure aims to provide a novel automobile charger with the safe power supply charging quickly, in order to solve the problems presented in the above background.

To achieve the purpose described above, the present disclosure provides the following technical solutions: a novel automobile charger comprises a direct current power supply, wherein a positive pole of the direct current power supply is connected with one end of a DC to DC module, one end of a battery voltage detection module and one end of a load module simultaneously, while a negative pole of the direct current voltage is connected with the other end of the DC to DC module, one end of a microcontroller, one end of an automobile start control module and the other end of the battery voltage detection module simultaneously. A third end of the DC to DC module is connected with the other end of the microcontroller, and the other three ends of the microcontroller are connected with the third end of the battery voltage detection module, the other end of the automobile start control module and one end of the load detection module respectively, wherein the other end of the load detection module is connected with the third end of the automobile start control module and the other end of the load module simultaneously; the load module which comprises the automobile storage battery and the automobile engine is located on the end of the load module.

As a further solution of the present disclosure that: the DC to DC module provides a stable voltage for the microcontroller which collects relevant data to conduct the corresponding control. The battery voltage detection module conducts the measurement of the batter voltage, the automobile start control module conducts the power supply or the power outage for the load module through the microcontroller, and the load detection module which comprises the automobile storage battery or the automobile engine detects whether the load module is correctly connected.

As a further solution of the present disclosure that: the circuit employs an electronic switch to supply power to the load module, which can offer more protection for the product, or reduce the product size and the material cost.

As a further solution of the present disclosure that: the battery voltage detection module provides protection for the power supply battery to prevent damages caused by the discharging of the direct current power supply.

As a further solution of the present disclosure that: the load detection module prevents improper operations of the user.

As a further solution of the present disclosure that: in the standby mode, the microcontroller closes all outputs when the voltage of the direct current power supply is lower than that of the state being able to supply power and then recovers when it is higher than that of the state being able to supply power.

As a further solution of the present disclosure that: the automobile start control module is the electronic switch.

Compared to the prior art, the present disclosure has the beneficial effects that:

1. The present disclosure employs the electronic switch to control the supply power for the load, this part can offer more protection for the product, and reduce the product size and the material cost.

2. The battery detection of the present disclosure can provide low voltage protection to prevent damages caused by the over discharging of the battery.

3. The load detection of the present disclosure can prevent improper operations by the user, such as reversed polarity, which causes damages to the automobile or the direct current power supply.

4. The present disclosure employs the voltage backflow protection for abnormal load, wherein the automobile start line is closed to protect the battery when the abnormal voltage is detected.

5. The present disclosure has a fast charging function, and can be installed fixedly or moved portably according to the use requirements of people.

6. The automatic detection module of the present disclosure can automatically detects whether the load is connected, whether the electrode is connected with the automobile storage battery reversely, whether the automobile engine or the storage battery has reverse current, whether the battery state is suitable for heavy current power generation, thereby protecting the load and the circuit and thus has complete functions.

BRIEF DESCRIPTION OF DRAWINGS

FIG. 1 is a block diagram for the principle of the emergency power supply of the safe intelligent automobile;

FIG. 2 is a circuit diagram for the emergency power supply of the safe intelligent automobile.

In figures: 1—DC to DC module, 2—microcontroller, 3—battery voltage detection module, 4—automobile start control module, 5—load detection module, 6—load module, 7—direct current power supply.

DETAILED EMBODIMENTS

The technical solutions of the present disclosure will be described more clearly and fully in conjunction with drawings in the embodiments of the present disclosure, and obviously, the described embodiments are merely a part of the embodiments of the present disclosure, not all the embodiments. Based on the embodiments of the present disclosure, all the other embodiments obtained by the ordinary skilled in the art without creative labors belong to the scope claimed by the present disclosure.

Refer to FIG. 1, a novel automobile charger comprises a direct current power supply, wherein the positive pole of the direct current power supply is connected with one end or lead of the DC to DC module, one end of the battery voltage detection module and one end of the load module simultaneously, while the negative pole of the direct current voltage is connected with the other end of the DC to DC module, one end of the microcontroller, one end of the automobile start control module and the other end of the battery voltage detection module simultaneously. A third end of the DC to DC module is connected with the other end of the microcontroller, and the other three ends of the microcontroller are connected with the third end of the battery voltage detection module, the other end of the automobile start control module and one end of the load detection module respectively, wherein the other end of the load detection module is connected with the third end of the automobile start control module and the other end of the load module simultaneously; the load module which comprises the automobile storage battery and the automobile engine is located on the end of the load module.

Refer to FIG. 2, the DC to DC module comprises a diode D1, a resistor R1, capacitor C1, a HT7530 voltage stabilizing tube, capacitors C2 and C3, wherein the positive pole of the diode D1 is connected with the positive pole of the battery, the negative pole of the diode D1 is connected with one end of the capacitor C1 and an IN port of the HT7530 voltage stabilizing tube simultaneously through the resistor R1, and an OUT port of the HT7530 voltage stabilizing tube is connected with one end of the capacitor C2, one end of the capacitor C3 and a VDD port of the microcontroller U2, while the other end of the capacitor C1, the other end of the capacitor C2 and the other end of the capacitor C3 as well as a GND port of the HT7530 voltage stabilizing tube are grounded and connected with the negative pole of the battery simultaneously; a R1 port of the microcontroller U2 is connected with the negative pole of the battery through a light-emitting diode L1 and a resistor R12 which are in series connection, a B1 port of the microcontroller U2 is connected with a EN port of the automobile start control module, a V0 port of the microcontroller U2 is connected with the negative pole of the battery through a capacitor C4 and a resistor R7 which are in parallel connection, the V0 port is also connected with the VDD port through a slide rheostat RT, a V1 port of the microcontroller U2 is also connected with the negative pole of the battery through a resistor 10, a capacitor C6 and a resistor R13 which are in parallel connection, the V1 port is connected with the positive pole of the battery through a resistor R2, and is also connected with the negative pole of the automobile storage battery and the automobile engine simultaneously through a resistor R9, wherein two ends of the automobile storage battery are in parallel connection with the capacitor C7, resistors R9, 10, a capacitor C6 and a resistor R13 to form the load detection module together, a V4 port of the microcontroller U2 is grounded through a capacitor C5, a VSS port of the microcontroller U2 and one end of the capacitor C4 are grounded simultaneously. The other end of the capacitor C4 is connected with the VDD port of the microcontroller U2, the resistors R2, R13 and capacitor C6 form the battery voltage detection module together, and a Drive port of the automobile start control module is connected with the automobile engine and one end of a resistor R14 simultaneously, wherein the other end of the resistor R14 is grounded.

The DC to DC module in the present disclosure provides the stable voltage for the microcontroller which collects relevant data to conduct the corresponding control. The battery voltage detection module conducts the measurement of the batter voltage, and the automobile start control module conducts the power supply or the power outage for the load module through the microcontroller, wherein the load detection module detects whether the load module is correctly connected.

The microcontroller in the present disclosure determines whether the automobile storage battery is connected with the automobile engine through the load detection module, wherein the automobile start control model is automatically activated and the battery starts to supply power to the load module when the load is correctly connected; the automobile start control model is automatically deactivated and the battery stops supplying power to the load module when assuming that the load is not connected or the positive and negative polarities are reversely connected. In the standby mode, the microcontroller closes all outputs when the battery voltage is lower than 9V, and recovers the normal operation only when the battery voltage is larger than 10V; the automobile engine will generate the normal voltage to recharge the battery after the automobile starts, whereas the automobile start control module is deactivated immediately once the recharging voltage is larger than the voltage before that battery starts the power supply, to protect the battery from damages caused by charging with the normal voltage; the automobile start control module is the electronic switch, which can prevent the load from being reversely connected and recharging of the normal voltage, thus protecting the battery and prolonging lifespan.

The automobile engine will generate abnormal voltage to recharge the direct current power supply after the automobile starts, and the automobile start control module is deactivated immediately once the recharging voltage is larger than the voltage before the direct current power supply starts the power supply, to protect the direct current power supply from damages caused by charging with normal voltage charge.

It is obvious for the skilled people in the art that the present disclosure is not merely limited to the details of the above exemplary embodiments, and the present disclosure can be implemented in other specific forms without departing from the sprits or the basic features of the present disclosure. Thus, no matter to consider from which point of view, the embodiments should be considered as exemplary and non-limiting. The scope of the present disclosure is defined by the accompanying Claims rather than the above description, therefore it is intended that all the changes fallen within the meanings and scope of the equivalent elements of the Claims are contained in the present disclosure. Any drawing reference in the Claims should not be regarded as limiting the Claims involved.

Furthermore, it should be understood that although the specification is described according to the embodiments, but not every embodiment includes only an independent technical solution, this manner of description for the specification is only for clarity, therefore the skilled people in the art should take the Specification as a whole, and the technical solutions in various embodiments can be combined appropriately to form other implementations understandable for those skilled in the art. 

What is claimed is:
 1. An automobile charger, comprising: a first pole of a first battery connected with a first lead of a power converter, a first lead of a battery level detector, and a first lead of a load; a second pole of the first battery connected with a second lead of the power converter, a first lead of a microcontroller, a first lead of a switching circuit and a second lead of the battery level detector; a third lead of the power converter connected with a second lead of the microcontroller; and three additional leads of the microcontroller connected with a third lead of the battery level detector, a second lead of the switching circuit and a first lead of a load detector, respectively, wherein a second lead of the load detector is connected with a third lead of the switching circuit and a second lead of the load, and wherein the load includes a second battery and a motor.
 2. The automobile charger according to claim 1, wherein: the power converter includes a one-way current device, a resistance R1, a capacitance C1, a voltage stabilizing device, a capacitance C2 and a capacitance C3; a first terminal of the one-way current device is connected with the first pole of the first battery; a second terminal of the one-way current device is connected with a first lead of the capacitance C1 and an IN port of the voltage stabilizing device through the resistance R1; an OUT port of the voltage stabilizing device is connected with a first lead of the capacitance C2, a first lead of the capacitance C3 and a power port of a microcontroller U2; a second lead of the capacitance C1, a second lead of the capacitance C2 and a second lead of the capacitance C3 as well as a common port of the voltage stabilizing device are grounded and connected with the second pole of the first battery; a first port of the microcontroller U2 is connected with the second pole of the first battery through a light source and a resistance R12 in series connection; a second port of the microcontroller U2 is connected with an input of the switching circuit; a third port of the microcontroller U2 is connected with the second pole of the first battery through a capacitance C4 and a resistance R7 in parallel connection and is also connected with the power port through a variable resistance RT; a fourth port of the microcontroller U2 is connected with the second pole of the first battery through a resistance R10, a capacitance C6 and a resistance R13 in parallel connection; the fourth port of the microcontroller U2 is also connected with the first pole of the first battery through a resistance R2 and is also connected with a first pole of the second battery and the motor through a resistance R9; two leads of the second battery are in parallel connection with the capacitance C7, the resistances R9, R10, the capacitance C6 and the resistance R13 together to form the load detector; a fifth port of the microcontroller U2 is grounded through a capacitance C5; a common port of the microcontroller U2 and one end of a capacitance C4 are grounded; the second lead of the capacitance C4 is connected with the power port of the microcontroller U2; the resistance R2, the capacitance C6 and the resistance R13 form the battery level detector; and an output of the switching circuit is connected with the motor and one end of a resistance R14, wherein the other end of the resistance R14 is grounded.
 3. The automobile charger according to claim 1, wherein: the power converter is operably configured to provide a stable voltage for the microcontroller which collects relevant data to conduct a corresponding control; the battery level detector conducts a measurement of a voltage of the first battery; and the switching circuit conducts power supply or power outage for the load through the microcontroller, wherein the load detector detects whether the load is correctly connected.
 4. The automobile charger according to claim 1, wherein the battery level detector is further configured to provide a protection for the first battery.
 5. The automobile charger according to claim 1, wherein the microcontroller, when placed in a standby mode, closes all outputs when a voltage of the first battery is lower than that of a state being able to supply power and then recovers when the voltage of the first battery is higher than that of the state being able to supply power.
 6. The automobile charger according to claim 1, wherein the switching circuit is an electronic switch.
 7. A charging device, comprising: a battery level detector to detect a level of a first battery; a load detector to detect a type of connection of a load; a microcontroller to generate an output signal based on the level of the first battery and the type of connection of the load; and switching circuitry to selectively connect the first battery to the load based on the output signal.
 8. The charging device of claim 7, wherein the type of connection includes a proper connection of the load and an improper connection of the load.
 9. The charging device of claim 8, wherein the load is a second battery and a motor powered by the second battery.
 10. The charging device of claim 9, wherein the proper connection of the load is a polarity match between the second battery and the motor, and wherein the improper connection of the load is a polarity reversal between the second battery and the motor or a disconnection of the second battery from the motor.
 11. The charging device of claim 8, wherein the microcontroller is configured to: generate the output signal to cause the switching circuitry to connect the first battery to the load if the load is properly connected and the level of the first battery is above a threshold; and generate the output signal to cause the switching circuitry to disconnect the first battery from the load if i) the level of the first battery is below the threshold, or ii) the load is improperly connected.
 12. The charging device of claim 7, wherein the battery level detector detects a recharging level of the first battery.
 13. The charging device of claim 12, wherein the microcontroller generates the output signal to cause the switching circuitry to disconnect the first battery from the load if the recharging level of the first battery is greater than a threshold.
 14. The charging device of claim 7, further comprising: a power converter to convert power received from the first battery into a stable power source that powers the microcontroller.
 15. The charging device of claim 14, wherein the power converter is a direct current to direct current (DC-DC) converter.
 16. The charging device of claim 7, wherein the level of the first battery is a voltage level.
 17. A method, comprising: detecting a level of a first power source; detecting a type of connection of a load; generating an output signal based on the level of the first power source and the type of connection of the load; and selectively connecting the first power source to the load based on the output signal.
 18. The method of claim 17, wherein the type of connection includes a proper connection of the load and an improper connection of the load.
 19. The method of claim 18, wherein the load is a second power source and an electrical component powered by the second power source, wherein the proper connection of the load is a correct polarity connection between the second power source and the electrical component, and wherein the improper connection of the load is an incorrect polarity connection between the second power source and the electrical component or a disconnection of the second power source from the electrical component.
 20. The method of claim 18, the generating comprising: generating the output signal to cause the switching circuitry to connect the first power source to the load if the load is properly connected and the level of the first power source is above a threshold; and generating the output signal to cause the switching circuitry to disconnect the first power source from the load if i) the level of the first power source is below the threshold, or ii) the load is improperly connected. 